This application claims the benefit of priority of U.S. provisional application No. 61/625,447, filed Apr. 17, 2012, the contents of which are herein incorporated by reference and U.S. Non-provisional application Ser. No. 14/039,973, filed Jul. 14, 2014.
The present invention relates to concrete forms and, more particularly, to a masonry connector that positions opposing masonry shells in a level and plumb manor for use as STAY-IN-PLACE form work.
Concrete Masonry Units (CMU) are used in the construction of walls in buildings but have disadvantages that are costly to overcome. Block construction involves stacking CMU blocks in a grid pattern (typically 16 inch×8 inch grid) to form a wall. CMU is manufactured in a molding process that results in blocks that can vary in size plus or minus ⅛ inch within the height of a block.
Dry-stacking blocks with these inconsistencies in height would result in a wall that is out of plumb and level. The masonry industry has solved this problem by manufacturing CMU blocks to a size (typically 15⅝ inch×7⅝ inch) slightly smaller than their intended grid size. These masonry blocks are then stacked with a bed of mortar (typically ⅜ inch), to compensate for the smaller size, keeping the wall construction in line with the grid pattern established.
A skilled mason lays mortar on the previous course of CMU blocks thicker than required, stacks the next course of block on top of the mortar and taps on the top of the block until he compresses the mortar down and out so that the combination of the block and the mortar lines up with the grid pattern.
This process results in mortar thickness that varies to compensate for the inconsistent heights of plus or minus ⅛ inch in CMU masonry units and allows for the construction of plumb and level masonry walls.
Using STAY-IN-PLACE concrete forms constructed of concrete masonry shells with plastic web members is an alternative wall construction method that has been limited due to high labor cost associated with mortaring shells in place.
The present invention is a plastic connector that enables masonry shells of inconsistent dimensions with preformed channels to be snapped together while maintaining a gap of variable thickness between the shells such that the masonry shells and the gap fall within a predetermined grid pattern. The connectors perform the function of mortar joints in masonry construction while reducing the time, labor and skill required by eliminating mortaring joints as the masonry is set.
Mortar also has a set time that requires a waiting period before moving on to the next row of masonry shells. The present invention's plastic connectors have no set time. Masonry shells can be snapped together to form the opposing walls of a stay in place concrete form with no wait time, less labor and skill, while maintaining a predetermined grid pattern.
The connectors are also configured to accept plastic cross ties. Cross ties are required in concrete form work to restrain poured in place concrete between two opposing form walls.
The viscosity of the poured in place concrete can be controlled such that the uncured concrete will not leak out of the small variable gaps maintained by the plastic connector. Once the poured in place concrete has been cured, the gaps between the masonry shells can be left open, can be filled with caulk, can be filled with adhesive, or can be filled with mortar.
Prior art does not properly address using masonry shells of variable dimensions as the walls of concrete form work. Using shells of variable dimensions without compensating for this variation will result in walls that are out of plumb and level. Prior art teaches stacking and snapping together shells with consistent dimensions. Prior art teaches using mortar joints or adhesives or caulk to compensate for variations in shell sizes. The present invention teaches how to snap shells of inconsistent dimensions together with a plastic connector that compensates for the inconsistencies incrementally with each course of shells.
Conventional stay-in-place masonry forms come in the form of blocks that needed to be mortared into place, the same as normal masonry construction.
As can be seen, there is a need for an improved stay-in-place concrete form connector that allows masonry shell of variable dimensions to be dry stacked to form the walls of concrete form work.
In one aspect of the present invention, a method of connecting concrete masonry shells together with plastic connectors that adjusts the height of the shells to a consistent height for use in a stay in place concrete form.
The plastic connectors are configured to fit tightly in a channel formed in the masonry shells. The friction from the tight fit of the assembly with the channel formed in the masonry shell unit allows for the height of the shell unit and the plastic assembly combined to match a predetermined block coursing. Force is applied to the assembly (such as tapping with a rubber mallet) reducing the height of the assembly by sliding a tongue in the connector into a channel in the shell. The force is discontinued when the assembly meets the height requirements. The friction resistance between the tongue (a dovetail dowel in one embodiment) and the channel must be great enough to hold up the weight of the masonry shell but small enough to allow movement when the external force (tapping rubber mallet) is applied.
The plastic connector would also have an indentation (hole) formed as part of the connector to accept a geometric plastic cross tie of uniform shape. The plastic cross ties would connect an interior and exterior shell assembly together the combination of which will act as a stay in place concrete form.
In one embodiment, the plastic cross ties consist of ½ inch diameter pvc pipe. The pvc plastic cross ties can be cut to any length. The thickness of the concrete wall formed inside of this cavity is determined by changing the length of the plastic cross ties to match the desired concrete wall thickness plus the desired insulation thickness. The plastic cross ties fit into a hole formed in the connector that is part of the shell assembly of consistent height on both the exterior and the interior. The plastic cross tie is either glued or screwed after it is inserted into the plastic connector on both sides.
Sheets of rigid insulation can be placed on one or both interior faces of the masonry shells before attaching the ½ inch diameter pvc plastic cross ties. The plastic cross ties are then pressed through the rigid insulation as the cross ties are inserted into the plastic connectors on the opposing wall assemblies of the stay in place concrete form.
In one embodiment, the plastic connectors have a wedge shim protrusion to act as a guide to set the height of the gap between the stacked masonry shells. The wedge shim would be operable by expanding the thickness of the shim. The wedges shim would spread apart or move together by threading a screw into the wedge shim as required to obtain the proper gap height.
In one embodiment, the channels formed in the masonry shells at regular intervals to accept the plastic connectors are dovetail shaped channels and the plastic connectors are dovetail shaped dowels of a predetermined height to match the shape of the masonry shell channels. Half of the height of the dovetail shaped dowel is embedded in the dovetail channel formed in a masonry shell. The dovetail shaped dowels are placed in pairs in the top of a pair of channels formed in a masonry shell. The second half of the height of the dovetail shaped dowels extends above the masonry shell. A second masonry shell with matching dovetail shaped channels then slides over the extended portion of the dovetail shaped dowels. The dovetail shaped dowels are slightly larger than the channels in the masonry shell such that force is required to deform the dovetail shaped dowels into the channel. Through friction between the dowels and the channels, the masonry shells are locked in place to the pair of dowels and in turn the shells are also connected together by the dowels. This allows for multiple levels of masonry shells to be connected together, stacked one on top of another, to form the walls of stay in place form work.
In one embodiment, the lower half of the dovetail shaped dowel has protruding friction teeth. The teeth extend outside of the dovetail shape of the dowel such that the dovetail dowel will not slide into the masonry shell dovetail channel. A large force (such as hammering the top of the dovetail dowel with a rubber mallet) is required to deform the friction teeth and force the lower half of the dovetail shaped dowel into the top of the masonry shell dovetail channel locking the dovetail dowel in place through friction.
In one embodiment, the upper half of the dovetail shaped dowel has a hole in the side of the dowel to accept attachment of a ½ inch pvc pipe cross tie. The top of the dowel has a wedge shaped pilot hole. One function of the pilot hole is to guide a screw through the top of the dowel and into the pvc pipe cross tie to connect the two separate parts together. The connector and the cross tie are connected together before the next masonry shell is stacked onto the upper half of the plastic connector's dovetail dowel.
In one embodiment, a second masonry shell with dovetail shaped channels slides down onto the upper half of the pair of dovetail shaped dowels extending up from the masonry shell described two paragraphs above. Only light force is required to force the masonry shells onto the dowels. The height of the masonry shell is adjusted by the wedge shims described above. This adjustment results in a plumb and level installation. A second function of the wedge shaped pilot hole is to expand the upper half of the dovetail dowel once the dowel is properly positioned to lock the upper half of the dovetail dowel in place inside of the dovetail channel. The same screw that attaches the pvc plastic cross tie to the dovetail dowel is screwed in further until the wider head of the screw enters the wedge pilot hole. As the wider head of the screw enters the wedge the top half of the dovetail dowel expands locking the dovetail dowel in place through friction inside of the dovetail channel.
These steps are repeated stacking one masonry shell on top of another masonry shell until the required height of concrete form work is achieved.
These and other features, aspects and advantages of the present invention will become better understood with reference to the following drawings, description and claims.
The following detailed description is of the best currently contemplated modes of carrying out exemplary embodiments of the invention. The description is not to be taken in a limiting sense, but is made merely for the purpose of illustrating the general principles of the invention, since the scope of the invention is best defined by the appended claims.
Broadly, an embodiment of the present invention provides a stay-in-place concrete form connector including masonry shells layered with rigid insulation tied with plastic cross ties. The masonry shells can be adjusted with plastic connectors that compensate for the variation in height of the shells. This allows for the shells, together with the connectors, to be a consistent height and allows for dry stacking. This dry stacking method can result in labor time and training savings over conventional masonry mortar construction.
Conventional formed concrete walls do not have a desirable appearance and require additional steps to insulate and finish when used as a structural wall in buildings. The present invention solves this problem.
Stay-in-place forms eliminate the need to strip off temporary forms for concrete wall construction. Adding insulation to the concrete wall in a later step is not required as insulation can be integrated into the stay-in-place form. The stay-in-place form can act as an exterior and/or interior wall finish that is desirable to the end user.
Prior to the present invention, stay-in-place block forms came in the form of blocks that needed to be mortared into place, the same as normal masonry construction. The present invention eliminates the need to mortar joints, allows for up to two layers of rigid insulation, adding to the insulation value of the assembly while also improving moisture resistance, and sound deadening characteristics.
The present invention can be assembled in the field which allows for this assembly to be constructed around construction obstacles such as vertical reinforcement bars in concrete and/or embedded utility piping.
Concrete wall forms consist of two vertical surfaces connected by ties spaced at close intervals so that when concrete is poured between the two surfaces they are held in place by equal and opposite forces induced by the wet concrete. The plastic connector of the present invention makes it practical and affordable to use masonry shells of inconsistent dimensions as those vertical surfaces.
Referring now to the Figures, a split plate metal mold with injection ports is manufactured to produce injection molded polypropylene parts 100 in the configuration shown in
The present invention's dovetail shaped dowel 100 act in pairs as a connector to join masonry shells of inconsistent dimensions 300 together for use as stay in place concrete form work. Referring now to
Dovetail shaped dowel connector 100 shown in
Referring now to
Referring now to
If optional insulation is required then sheets of insulation can be placed against one or both interior faces of masonry shells 300. The pvc cross tie 400 is simply pushed through the soft rigid insulation as required to make the connection between the pair of dovetail dowel connectors 100. A pair of cement board screws 202 are driven into the top of dovetail dowel connector 100 through wedge shaped 126 pilot holes 124 and through the pvc cross tie 400 locking the cross tie in place. The head of the cement board screws 202 must not engage the wedge 126 of the wedge shaped pilot hole at his time.
Referring now to
Referring now to
It should be understood, of course, that the foregoing relates to exemplary embodiments of the invention and that modification may be made without departing from the spirit and scope of the invention as set forth in the following claims.
Number | Name | Date | Kind |
---|---|---|---|
2029082 | Odam | Jan 1936 | A |
3292893 | Williams | Dec 1966 | A |
4698947 | McKay | Oct 1987 | A |
4730422 | Young | Mar 1988 | A |
4750308 | McKay | Jun 1988 | A |
4765109 | Boeshart | Aug 1988 | A |
5107648 | Roby | Apr 1992 | A |
5224314 | Chen | Jul 1993 | A |
5430983 | Taipalensuu | Jul 1995 | A |
6151856 | Shimonohara | Nov 2000 | A |
6230462 | Beliveau | May 2001 | B1 |
6293067 | Meendering | Sep 2001 | B1 |
6438918 | Moore et al. | Aug 2002 | B2 |
7347029 | Wostal et al. | Mar 2008 | B2 |
8424835 | McDonagh | Apr 2013 | B2 |
20130269275 | Ryan | Oct 2013 | A1 |
Number | Date | Country | |
---|---|---|---|
20160168849 A1 | Jun 2016 | US |